Apparatus for photographing and exhibiting a multiplicity



y 13, 1952 F. E. TUTTLE ET AL 2,596,740

APPARATUS FOR PHOTOGRAPHING AND EXHIBITING A MULTIPLICITY OF DIFFERENT PICTURES IN SUCCESSION Filed Nov. 1'7, 1949 4 Sheets-Sheet l F ORDYCE E. TUTTLE WILLIAM BORNEMINN INVENTORS BY M W ATTORNEYJ y 13, 1952 F. E. TUTTLE ET AL 2,596,740

APPARATUS FOR PHOTOGRAPHING AND EXHIBITING A MULTIPLICITY OF DIFFERENT PICTURES IN SUCCESSION Filed Nov. 17, 1949 4 Sheets-Sheet 2 F ORDYCE E .TUTTLE I'VILLLAM BORNEMNN I N VE N TORS W 9. B Y

y 13, 1952 F. E. TUTTLE ET AL 2,596,740

APPARATUS FOR PHOTOGRAPHING AND EXHIBITING A MULTIPLICITY OF DIFFERENT PICTURES IN SUCCESSION 4 Sheets-Sheet 3 Filed Nov. 17, 1949 FIGJO.

FIG. 16.

I "ME ME R1 v w M W ma ms 3 FORDYCE E TUT TLE I'VILLIAM BORNEJIANN INVENTORS A TTOR NE ;5

2,596,740 ICITY M y 1952 F. E. TUTTLE ET AL APPARATUS FOR PHOTOGRAPHING AND EXHIBITING A MULTIPL- OF DIFFERENT PICTURES IN SUCCESSION 4 Sheets-Sheet 4 Filed NOV. 17, 1949 F ORDYCE E. TUTTLE W'ILLIAM BQRNEZiANN FIG. 12

INVENTORS *ITTORNE "S" Patented May 13, 1952 1APPARATUS"FOR rno'roempnmo AND :axmmrme A 'MULTIPLICITY F DIF- FERENT PICTURES IN SUGC SSIQ ;"Fn d e tfl an m- QIMmannrBmhester,.N; Y., assignors to Eastman 'KodakCome DBJIY ROQhGStBY, 'N. Y., a corporation of New Jersey Application November 17, 1949, .SerialNo. 121,851

The presentiinv n on relates tophotosr ph and particularly to an apparatus .for photographing and exhibitinga multiplicity .of different pictures in succession, on a singleareaof a light-sensitive surface.

The primary object, of the present invention is torp rovide a apparatus. for carrying .out the method of photographing andexhibiting amultiplieity ,of vv(liflferent ,.pictu res disclosed and clairned in U. S. patent application Serial No. 127,852, filed on. even; date herewith.

One object of the presentinvention is to provide a camerafor. phQtographing a multiplicity of ,diff erentpicture on a single frame of lightsensitive film, each picture having substantially the same. overall dimensions as the frame of film exposed.

,Another object is to provide a camera includinga scanning .disk through which theindividual exposures are made on the film ascomposite pictures in ;the form .of dot Y. patterns, said film andscanning disk being: moved relative to one another during or between exposures, depending upon. whether motion pictures or merely difierent still subjects, vrespectively, aretonbe photographed.

.Anqyet .anothenobject is to provide a camera of .the .type .described which .is particularly adapted f or taking high-speed motion pictures, and in which said scanning disk is I'Qtated. at relativelyhigh speed infront of-the film; plane during. exposure; and a capping shutter mechanism is associatedwiththe scanning. disk to control the. film exposure andprevent. double. exposure of, the film.

And stillafurther object is to provide a camera" of the type set forthin which thecappin shuttencan be selectively rendered inoperative so that thecamera. can be, used to takea plurality of difierent stillsubjects on the. same frame otii inr or. can b use tota e. m tio ictures 0 s bjects w s v e t s not fa t enou ht requi 1 th .115 O t ca pi g shu o th t .t eca ra can eu ed. as n xh in evice ior exhibiting pictures taken bythe user th eo And, another object is to provide a camera ;of the type disclosed in whichthe cappingshutter rotates with the scannin disk and is indexed relative to the disk by a spring toeffect the eX-. posures, ,and in which means are providedfor selectively adjustingthe tension .of the driving spring for the capping shutter inaccordance with. dilf rent Selected exposure speeds.

Still another object is to provide a camera by wh h a min mum of 91 0, d fierent qomppsi pi ve 1 100, 0 00 p c ur n l s e d- And, another object is to provide a camera of the type described which includes a novel means forreadily loading a film into the same and ,accuratelyloeatingit in thefocal plane, of thetaking lens.

A her. ob c ht r sentinveniionis t providea cameraof the type described which can also. be used as an exhibitor for the frame of .fllm exposed in the device when used as a cam ra- The novel features that we consider characteristic of our invention, are set forth with particularityvin the appended claims. ,Tljhe invention itself, 7 however both as to its. organization, and itsmethods of operation,togetherwithadditional objects and advantages thereof, willwbest be understood from the ,f ollowing description when read in connection with the accompanying drawings, in which: i

Fig. 1 is a partialfrontview of ascanningdisk, i the c tur s-a dih nrelati di pl m Ob ous y w o sca arthroueh wh h e p su s accordin t themes-ant inv ntion. ar mad 'Fig. 21s an enlarged viewsof. a portion; of the scanningdiskshown.inrFig. 1 and showing generally. the light-transmitting. apertures and their relative disposition andsize. Herev again, for reasons which will be obvious, the a scale isnot true-alt is exaggerated;

Fig. 3-is afurtherenlarged detail of aportion of the scanningdisk including :three successive apertures ofone spiral seriesand indicating their relative spacing -bothcircumferentially-and radially of thewdisk as compared -to their diameter inonespecial case used for purposes of disclosing the present invention;

Fig. 411s a diagrammatic-"showing of how any four successive;apertures-in onespiral series scan a portion of :the film in-the focal plane as the disk is rotated relative thereto;

--Fig. 5 is a side view, part-lydn section and partly in elevation, of a camera by the use of which the method of making photographs and exhibiting them according tothe invention disclosed in-the above-notedcopending application maybe practised;

' Fig. 6 is an enlarged perspectiveydetail of a portion of 1 the scanning disk and the capping shutter associated therewith and shown in opn. succession int rmitten 13? th ra of erative relation to clearly point out the function and operation of the capping shutter;

Fig. 7 is an elevational view of one side of the supporting plate for the scanning disk and showing the releasable clutch mechanism between the scanning disk and the capping shutter;

Fig. 8 is an enlarged sectional view of the driving means for both the scanning disk and the capping shutter;

Fig. 9 is an elevational detail looking down on the top of Fig. 8 and showing the means for cocking the capping shutter and varying the initial tension of the driving spring therefor;

Fig. 10 is a view taken substantially on line ll0 of Fig. 8;

Fig. 11 is an enlarged sectional detail through the periphery of the scanning disk, capping shutter and photographic plate, and showing the relative size and spacing of these parts on an exaggerated scale, and showing how the capping shutter is confined to a given plane of rotation by a guiding flange on the periphery of the scanning disk:

Fig. 12 is an enlarged rear view of that portion of the camera on which the plateholder is removably mounted and showing the plateholder mounted thereon;

Fig. 13 is a view taken substantially on line i3-i3 of Fig. 12 and showing the means in the back of the camera for accurately locating the photographic plate in the focal plane;

Fig. 14 is an enlarged sectional detail of the lower corner of Fig. 13 and illustrating the manner of adjustably mounting the photographic plate locating means in the back of the camera;

Fig. 15 is an enlarged elevational detail of a preferred form of photographic plate locating means mounted in the camera back taken substantially on line Il5 of Fig. 13; and

Fig. 16 diagrammatically illustrates another embodiment of apparatus by which the method of photography under consideration can be accomplished without the use of a capping shutter, as in the first-mentioned embodiment.

Like reference characters refer to corresponding parts throughout the drawings.

The present invention relates to a camera for carrying out the method of photography disclosed and claimed in copending application Serial Number 127,852, filed on even date herewith, and since an understanding of said method will facilitate an understanding of the purpose and function of the present camera, it will be reviewed herein. This method of photography concerns the production of a composite picture made up of widely displaced silver deposits with unexposed areas between them, much larger than the deposit size. The spacing of these silver deposits or elements making up one composite picture are so coarse as to provide room in the neighborhood of each for elements to be used for a great many more pictures; in the arrangement to be described, 899 other pictures. Such composite pictures are exposed on a given frame of a light-sensitive film by placing in the focal plane of a camera, and in front of the film, a scanning member provided with a great many minute apertures so distributed over the scanning member as to cover the entire area of the film in any one relative position of the scanning member and film. Such an exposure results in a composite picture made up of a multiplicity of separated silver deposits in the form of dots which, when developed or processed to a visible image and viewed in combination, give a complete image of the subject in which good definition, and even continuous tone effects as distinguished from a pattern of individual dots, are possible.

Since the making of such a composite picture requires the exposure of but a very small percentage of the entire area, then a great many such exposures can be made on a single frame of film if the exposures are made through a scanning member which positively selects for exposure only those elements or dots which constitute related parts of a picture. If each aperture (the scanning member as a whole) is translated to a new, non-overlapping position, unexposed emulsion is uncovered for the recording of an entirely new picture, while, at the same time, the scanning member covers the emulsion areas previously exposed. This method requires two-dimensional scanning of the focal plane, as distinguished from one-dimensional scanning as in grid type composite pictures described in copending patent application Serial No. 114,352, filed September '7, 1949, now Patent No. 2,578,327, issued December 11, 1951, since the composite picture, in this case, is made up of dot elements rather than linear strips.

Each of these composite pictures will preferably be made up of many thousands of individual minute dot elements, and each will have sub stantially the same overall dimensions as the frame of film. For instance, we have found, and this invention relates to, a camera by which it can be carried out, that a minimum of 900 difierent composite pictures can be exposed on a single 4 x 5" photographic plate, each composite picture being substantially 4" x 5" in overall dimensions. While these composite pictures when viewed by transmitted light through a scanning disk like that through which they were exposed will appear similar to well-known, half-tone pictures, and as good definition can be achieved as in half-tone pictures, they are not the equivalent of half tones in any sense of the word. Whereas in half-tone pictures the individual dots vary in size and density to produce the final image, in a composite picture made according to the present invention all of the dot elements will be of the same size and in each dot element there may be definition and resolution of the part of the image included in a single dot element.

Obviously, when the frame of film containing this multiplicity of composite pictures is processed to make the latent images visible, the processed film will appear to possess a maze of dots which mean nothing. However, it this processed film is viewed by transmitted light through the scanning member through which it was exposed, or an analyzing member similarly constructed, after properly registering the two. then the different groups of dot elements making up the different composite pictures will be simultaneously uncovered to bring out the different pictures. By moving the scanning member and the processed film relative to one another in precisely the same manner as was done in making the exposure, then a sequence of different pictures will be visible to the viewer. The best results are obtained by making these composite pictures in the form of transparencies and viewing them through the scanning member by transmitted light. If the original subject is a black-and-white drawing, or the like, the exposed film need only be processed to a negative transparency to be intelligible. However, if

reasons which will be obvious, the scale of the apertures in the scanning disk in these figures is far from true and the parts have only been indicated diagrammatically to show how the ntire photographic plate is scanned by the disk l3 in two dimensions. Looking at Figs. 1-3, the major portion of the scanning disk 13 is opaque to the rays to which the photographic plate is sensitive and is made up of radial lines of light-transmitting apertures M having a diameter d, and on each radius these apertures are separated by a distance equal to thirty times their diameter or 30d. One such radial line is labeled A in Fig. 2. Its adjacent neighbor radius B again has a series of apertures of diameter d spaced 30d apart as in A, but in each case of corresponding apertures between radial lines A and B those of B are a distance of d closer to the center of the disk than those of A. This is clearly illustrated in Fig. 3. Likewise, those of radial line C are d closer to the center of the disk than those of B. Radial lines A, B and C are mutually separated by a distance 30d. This process or spiraling in each radial series of apertures a distance d from radius to radius is continued for additional equispaced radii until the radius Z is reached on which the outermost aperture is only a distance d farther radially from the center of the disk than the first aperture of the next inner circumferential series beginning at radius A. Radius A corresponds to radius A in that all apertures thereon are at the same distance from the center as the corresponding ones on radius A.

From Fig. 2 it can be seen that the outermost aperture on radius A can progress linearly as far as radius A (or 900d) before it double exposes an emulsion spot previously exposed by its counterpart on radius A when radius A was at that position, and it was at A. It will thus be seen that with this configuration of apertures the photographic plate is scanned in two directions (both circumferentially and radially of the disk) as the disk is rotated relative thereto and a minimum of 900 composite dot-like pictures are recorded on the 4 x 5" photographic plate before a double exposure occurs. As will be evident from an inspection of Fig. 1, this described configuration of apertures is repeated completely around the disk so that the disk can be continuously rotated, and at any time a series of exposures is to be made, the disk is in position to properly scan the photographic plate.

We have found that a scanning disk having apertures whose diameter d is .0005 gives satisfactory results. In this case the apertures on each radius and in any circumferential series will then be spaced d or .015" apart and the disk will move through an arc of .450" in making at least 900 dot-like composite pictures on the 4" x 5" photographic plate. In order to cover a 4" x 5" photographic plate with this configuration of apertures, we have used a scanning disk 21" in diameter. The aperture configuration is disposed on the outer portion of the face of the disk so as to completely cover the 4" x 5" plate area at all times. Such a configuration of apertures of .0005" diameter when used to scan a 4 x 5" plate produces a dot pattern for each composite picture approximately 332 dots wide and 266 dots high; or, each composite picture is composed of some 88,445 dots. If it be remembered that at least 900 of these composite pictures are exposed on a single 4 x 5" photographic plate, then the plate has over 79,600,500 individual dot exposures thereon. This scanning disk need be rotated relative to the photographic plate at only 600 R. P. M. to attain a picturetaking rate of one million per second. By tripling this speed of rotation, or bringing it up around the normal speed of rotation of a conventional electric motor, a rate of exposure of three million per second can readily be attained. Likewise, slower exposure rates can be obtained by cutting down on the speed of rotation of the disk. If the diameter d of the aperture is .001, then the space of the apertures (30d) will be .030" and the disk will have to move through an arc (900d) or .9" before double exposure begins and during which movement 900 pictures are taken on the photographic plate.

If the outermost apertures of the disk travel .450" before they double expose in the assumed 4" x 5" case, it is obvious that the innermost apertures covering a 4" x 5" plate will travel less than .450 before they double expose because of the loss in circumference with a fixed angle as one moves toward the center of the disk. This condition can be eliminated if one makes the diameter of the apertures progressively smaller as a radial series progresses toward the center. In the 4" x 5" case, the diameter of the outermost and innermost apertures would be in a ratio of 10:6; i. e., the innermost would be .0003". In order to avoid the difficulty of making apertures as small as .0003 in diameter, it is preferable to make that group of apertures passing through and adjacent the center point of the photographic plate or optical axis .0005 in diameter and increasing and decreasing the size of the apertures as one moves out and in, respectively, on a radius in order to give the abovementioned 10:6 ratio. It will be appreciated that this aperture size difficulty is exaggerated in the illustrated case, because of the large size photographic plate (4" x 5") to be scanned, and because of the relatively small disk used to do the scanning. Should the size of the plate to be scanned be reduced, or the size of the disk be increased so that the scanning apertures move across the plate in substantially a straight line, or the aperture configuration is expanded circumferentially, then this difficulty can be avoided and all of the apertures could be the same size. This scanning disk may be made in a number of different ways, but we have found it particularly desirable to make it photographically on a glass photographic plate, because in this way the aperture size and spacing can be accurately controlled and maintained, and the glass plate is sufflciently rigid to hold its shape while rotating at high speeds.

We made the statement above that 900 composite pictures is the minimum number which will be exposed on the 4" x 5" photographic plate, and that actually the absolute number of pictures taken is more a function of how many grains of emulsion are uncovered per 900d movement of each aperture when taking motion pictures. A more comprehensive understanding of this phenomenon will be had from an examination of Fig. 4 which diagrammatically illustrates how four successive apertures of a circumferential series actually scan different linear areas of the photographic plate. If it be assumed that the disk is rotating counterclockwise at a continuous rate to take motion pictures, and each of the four apertures shown has moved from the dotted line position shown for two of them to the full-line position, it will be apparent that the leading edge of each aperture is continuously 9", uncoveringinew emulsion, while the trailing-edge iszcovering: that previously exposed. It is obvious: that when the apertures move a distance equal to their diameter they completely cover a previously'exposed area and uncover an entirely. new area, and that a complete new exposure. is made. This effect produces the 900 pictures we speak of as a minimum. However, let us assume that during the time it takes an aperture to move only'one-half of its diameter, the leading edge of the moving subject being photographed has moved from the position it was in when the aperture was in its last-assumed position. Then, so long as new emulsion is uncovered by the half diameter movement of the aperture, this new position of the leading edge of the subject will.

beexposed thereon. If we assume the same cons ditions for smaller increments of movements of the apertures, it will be found that for any inecrement of movement of an aperture, no matter how'small,v a separate exposure will be made on.

the newly uncovered emulsion. This reasoning will hold down to the point where the grain size or resolving power of the photographic emulsion limits the number of pictures which can actually be exposed on a given area of film. Accordingly, the total number of composite pictures which can be placed on a photographic plate by this method of exposure is determined by the accuracy of ones analysis of the exposed plate. Proof of this is found in the fact that when an exposed high-speed composite picture plate is examined with an analyzing disk, subject motion can be observed when the grid is moved less than the diameter'of the apertures, or less than .0005". This phenomenon is probably one reason why such smooth motion reproduction is available when examining these composite motion pictures through a continuously moving analyzing disk,

since" the successive pictures as viewed actually dissolve into one another without a sharp break as in the frames of conventional movie film.

When this method of photography is used for photographing motion pictures, some means must be provided for letting the image fall on photographic plate only so long as it takes the scanning disk to move relative to the plate through an arc equal in length to 900d or .450" in the as surned case, inorder to prevent double exposure of some or all of the composite pictures. There. are different ways in which this may be accomplished including making the exposure by means of one of the conventional gaseous dischar e lamps which gives a very bright illumination for a very short duration, and triggering t e lamp by the subject to be photographed. Obviously, the duration of effective illumination of the chosen lamp should be equal to or less than the time required for the scanning disk to move through an are equal to 900d.

Another way in which t is m'av be accomplished, and which we deem the preferred way. is by the use of a capping shutter disk rotated in assembly with the scanning disk already described. As indicated in Fig. 6, this capping shutter disk I5 is identical in all respects to the scanning disk |3 except that the apertures l5 are now slots several times as long as the diameter of the ap rtures M in the scanning disk and slightly wider than the diameter of said apertures. The two disks rotate in assembly with their apertures out of alignment until the shutter disk is given an added rotational kick by a coiled spring, es will be'described hereinafter. This indexing of the disks withrespect to one another is triggered by the event/to be photographed. The exposures taketplace as the apertures l4 in" the scanning disk .and 311311510135 HS in .the shutter disk: pass through registering'positionsas shown in Fig: 6; the length of: the slot Hi. and its Velocity relative to. the aperturev Ml in the scanning. disk being correct to: expose all of'the emulsion available to: a. given aperture during'its'translation of 900d; In its cocked position the shutter disk'is held'with its slots |6 out of alignment with the apertures |4.in. the scanning: disk so that no light can strike the: photographic plate, and after'being moved through the registering. position shown by its spring: drive arrivesata position with its slots" 5: out: of. aligmnentwith thetapertures l 4 in thez disk-al3r Referringtnow'to Figs"; 5-15, we' will describe-a preferred form of camera; by which thismethod of photographingv and exhibiting; pictures above described may be carried outin' accordance with the. present invention... As previously mentioned, the camera comprises an objective lens I 0; a'bo'dy portion ||,.'and a bellows I22. A photographic plate P is; located inzthe focal plane of the objective and theilens can be focused on this plane by the use of a groun'd'glass window I! in the sidewall of the body and a pivoted mirron' not shown, which may be swung into and out ofthe field. of. the objective by a knob |3 extending from the top of the camera body. The scanning disk I3 is rotatably disposed in front of the-photographic plate as close as ispractically possible, approximately .010", and is'fixed to a circular metal supporting p1ate"|9, which is, in turn, fixed to a flangeZil on a driving sleeveZl. This sleeve is journaledin bearings supported by a frame22' whichalso supports the camera and its'associated mechanism and; is rotated by a motor M througha gear train. T including a spur gear- 231 fastened to the right-hand end of the sleeve; looking at Fig. 5.

The capping shutter disk i5 is rotatably' disposed between the scanning disk" l3 and the photographic plate P. Inasmuch as it is desirable to have the scanning disk located as close to the focal plane as possible, this capping shutter should be made of as thin material as possible. We have found thata .007" thick steel disk provides a suitable capping shutter for the apparatus in question. The capping shutteris fastened' in anysuitablemanner to a circular driving plate'24 which is, in. turn, connected to the end of a driveshaft zi'rotatably mounted within the driving sleeve 2|. A torsion spring 26 encir cling the driving sleeve 2| has one end 21 fixed toa worrnwheel 28 effectively fixed to sleeve 2|, while its other end 29 is fastened to a driving pin 30 extending diammetrically through drive shaft 25' and through peripheral slots 3| in driving sleeve 2|. This torsion spring tends to rotate the capping shutter |5 relative to the scanning disk l3 so asto move the slots [6 therein across'theapertures I l in the scanning disk to effect the exposure, and since the relative movement required is only a few thousandths of an inch at the pe-" riphery of the capping shutter (determined by the length of the slots 6 in the capping shutter) only a very minute relative movement is required between shaft 25 and driving sleeve 2|.

Hence, peripheralslots 3| need be only slightly longer than the diameter of drive pin 30.

The capping shutter disk I5 is adapted to be positively connected to the scanning disk l3 to be rotated in assembly therewith by a releasableclutch mechanism of the form best shown in Fig.

7. Slidably mounted on the face of the driving plate I 9 is a bolt 33, normally moved to the right (looking at Fig. 7) by a spring 34 and adapted to be moved to the left upon energization of a solenoid 35 fastened to the plate I9 and to the plunger of which the bolt 33 is pivoted, as shown at 36. The top edge of the bolt 33 has a high surface 31 and a low surface 38 separated by a sharp riser portion 39. Fastened to the face of the drive plate 24 of the capping shutter is a latch member 40 which extends through an elongated slot 4| in the driving plate I9 of the scanning disk, so that its lower straight face is adapted to engage one of the surfaces 31 or 38 of the bolt 33. When the latch member 40 is in engagement with the high surface 31, the capping shutter is positively connected to the scanning disk with the torsion spring 26 cooked and the slots I6 in the shutter out of alignment with the apertures I4 in the scanning disk I3 and the disk and shutter can be rotated in assembly without passing light to the photographic plate. Now if the solenoid 35 is energized, the bolt 33 is pulled to the left to bring the low surface 38 of the bolt under the latch member 40, whereupon, due to the action of torsion spring 26, the capping shutter rotates relative to the scanning disk until latch member 40 engages the low surface of the bolt in which position the slots IS in the shutter are again out of alignment with the apertures I4 in the disk I3. During this relative movement of the scanning disk and shutter, the slots I6 in the latter move across the apertures I4 in the former to make the desired 900 composite exposures on photographic plate. Because of the small relative rotation required between the shutter and scanning disk to make the exposure, the riser 39 between surfaces 31 and 38 is only in the neighborhood of a couple of one-thousandths of an inch, and this relative movement occurs at a very high rate.

When the capping shutter I5 is in its cocked position, the slots I6 therein should be displaced from alignment with apertures I4 in scanning disk I3 just sufficiently to obtain a complete blocking of the light through the two, but not enough to necessitate the shutter moving any unnecessary distance relative to the scanning disk for the slots IE to start uncovering the apertures I4 in the disk. It is impractical to obtain such a close relative disposition of these two parts when mounting the described releasable clutch mechanism on the drive plates I8 and 24 so the following adjusting mechanism is provided to this end. A so-called rough adjustment is provided by nioimting the guideway 200 for the sliding bolt 33 on a block 23I fastened to the face of drive plate I9 by a plurality of bolts 2B2 passing through elongated slots in the block. After loosening these bolts 292, the adjusting screw 203, carried by a threaded bracket 204 on the drive plate I9, is turned to cause its end to adjust the block 2DI up and down. This causes the bolt 33 to move up or down and in turn shifts the shutter disk I5 relative to the scanning disk I3 through the latch member 40. A look nut 205 may be provided to hold the screw 203 in its adjusted position. A fine adjustment may be accomplished by turnin adjusting screw which has its end in threaded engagement with a tapped opening in the end of bolt 33. The end of the bolt is split, as indicated at 201, and a conical portion on the screw 206 is adapted to engage a conical recess in the end of the bolt to produce a wedging action which tends to spread that portion of the bolt engaged by latch member 40 when the screw is turned down. These adjustments. in addition to serving to accurately position the slots IS in shutter I5 relative to apertures I4 in scanning disk I3 when the two are in a cooked condition, may also be used, particularly the rough adjustment, to insure the latch member engaging the high surface 3! of bolt 33 as close to the riser 39 as possible when in a cocked condition to insure the solenoid moving bolt 33 far enough to release the latch member from the high surface 3's.

Inasmuch as the solenoid rotates with the scannin disk I3, means must be provided to energize the solenoid while it is rotating. To this end, one side of the coil of the solenoid is grounded through the plate IE] to the frame 22. The other side of the solenoid coil is connected by a wire indicated at 43 in Figs. 5 and 7 to a contact ring 44 fixed to the driving plate I9 by a plurality of insulating posts 45 so as to rotate with the plate. This contact ring 44 is in constant wiping contact with an electrical brush 45 mounted in and insulated from the frame 22 and to which one side of a source of potential, such as battery 47, diagrammatically illustrated in Fig. 5, is connected. The other side of the source of potential is grounded to the frame 22 as diagrammatically indicated. The solenoid circuit will include a switch indicated at 48 in Fig. 5 and when taking high-speed motion pictures, this switch will be triggered by the action to be photographed.

Inasmuch as the torsion spring 26 must index the capping shutter I5 relative to the scanning disk I3 at a relatively high acceleration, while the two are rotating together in a cocked rela tion, it will be understood that this torsion spring must be a relatively strong one for a set of parts of the dimensions set forth. By way of example, it has been found that a torsion spring having a strength of 200 pounds per square inch is suitable. To permit cooking the capping shutter I5 against a spring of this strength, a collar 50 is fixed to the end of drive shaft 25 extending beyond driving sleeve M and which collar includes a plurality of sockets 5I spaced around its periphcry and into which a rod 52 may be removably inserted, as shown in Fig. 9, to be grasped by the operator to move the shaft counterclockwise relative to driving sleeve 2I. This cocking action requires but a very minute movement of the shaft 25 relative to sleeve 2I and when the shutter reaches its cocked position the bolt 33 is moved to the right by its spring 34 to move the high surface 3! thereof under the latch member 40 and positively connect the shutter and disk together with the shutter in a cooked condition. When rod 52 is not being used, it is placed in a socket 53 in the frame 22, as shown in Fig. 5.

As mentioned above, the rate of exposure is controlled by the speed at which the scanning disk I3 is rotated relative to the photographic plate P. Since the speed of rotation of the scanning disk is controlled by the speed of the motor M and the ratio of the gears in train T, the speed of exposure can be readily altered by changing the ratio of the gears in the train. However, as the exposure speed and, hence, speed of rotation of the scanning disk and capping shutter is altered, a change in the acceleration rate of the capping shutter is required and this involves a change in the force of the torsion spring 26 when in a cooked condition. In order to permit changing the force of a spring as heavy as this torsion spring, in accordance with different exposure speeds, the following structure. is: provided; Mounted on a bracket/t fixed to a shoulderon the spur. gear23 fixed to the drivingsleeveZl is a worm 55 engaging the .wormwheel 28 to which one'end of the torsion spring is connected. Wormwheel ZBis actually rotatably mounted on the sleeve. Ell, although the ratio. between. the worm 5 and wormwheel 28 is such as tolockthe wormwheelagainst; rotation on the sleeve under the action of: torsion spring 2%. 3y placing a screw driver in the slot it in the end of theshaft of'theworm, the worm may be turned to, in turn, rotate the wormwheel 28 and end 21: of spring 26'relativetothe driveshaft 25 andidriving sleeve- 21'. To facilitate properadjustment: of this tor sion spring in accordance with..diiierenttselected:

exposure. speeds, the. shoulder of the wormwhe'el zatma'y be. inscribed with. a scale 5? cooperating with anindex mark 58 on the shoulder of the spur gear fixed to the driving sleeve; said scale being properly calibrated in exposure speeds,

As clearly. shown in Fig. 11, in order'to elimi:-. nate any possibility of the capping shutter l5 acoidentally deviating from its normal plane and engaging and...soratching the emulsion off from theiface of the'photographic' plate P, the scanning diskis provided with a metal rim 60, one edge of which includes av flange 6| in which the disk isseated; the other edge ofthe'rim extend.- ing beyondrthe face of the disk and' havingat;- tachedfthereto. a guiding ring. 62 which slightly overhangs, thecedge of the capping shutter'and hasiitsinner face lying ina plane slightly inside of the emulsion face e ofxthe photographic plate. In-normal operation the centrifugalforces acting on:thei oappingshutter will be suflicienttokeep it flat, despite the thinness-of its gauge, Any tendencvtof; the: capping shutter to deviate from its plane will. appear first at rthe extreme periphery" so that theguiding ring 62 will-be. efiectiveitox keep it: out of contact with: theemulsionof the photographic plate. As forthe: dangerof the capping shutter engaging the scanning disk1l3i and, scratching it, it must be rememberedthat, these: two parts rotate relative to one; another.

only during the-time an exposure-is being made, and. then only through an arc. of a few thousandths of= an inch, depending upon'the length of. the slot-s lfi inthecapping shutter. Ithas been. foundthat satisfactory'operation. is obtained if a .005 spacing is provided between the capping shutter; l5' and the photographic. plate P and a .002. -.003' 'spacing is provided-betweentheshutterRandthe -scanning .disk' l3. Assuming the. shutter-to be. .007 thick, then thefaceof. the scanning disk is spaced only .013"'from'the;fooal plane or-photographio plate. It will be under stood that if the scanning disk is made.photo graphically on glass plate, as assumed and shown, the emulsion surface of the disk will be adjacent thefocal plane so that the scanning apertures will bev as close as possible to thisplane...

ItWi-ll be; appreciated that someameans mustbe provided: for loading the photographic'plateP J into the camera without fogging the same'and for accurately positioning it in the focal plane so thati-t wont be contacted by therotating capping.-

shutter. To this end, the rear of thecamerabody II and its supporting frame 22 has attached thereto by screws 63 a cover plate Mwhich-covers the lower portion of the capping shutter l5 and scanningdisk l3 and is provided with a rectangular opening;65 over which a rectangular plate holder is adapted to beplaced, asshown in Figsr5; Hand 13.

This plate holder 68 is in the.v

formrofa .rectangul'anhouslng, the. front-;zwa-lli of: which isopenandof a size'to-match the opening; in. the back of; the. cover. plate. 64. This plate holder-'is-properly located on the coverplate bya. U-shape'd stop 67. on the, coveroplate which. en-.-. gages the bottom of-theholder to position it vertically: and two side; stops 68. on. the cover: plate. which engagev the opposite sides of? the. holder adjacent its top to: locate it horizontally; The plate holder'is detachablyheld onthecoveri plate by threeturnbuckles 69 whichare pivotedto thecoverplate 64 and adapted to engage notchesinthe flange, around the openface of the plate. holder. A gasket of velvet, plush, or. other suit-. able material: 10 isplaced on ..the faceof the margin.v surrounding. the opening in. the cover: plate inorder to make a light-tight joint; bee. tween; the: plate holder and. cover; plate when the? two are brought: together.

Fixed to the inner end of. a rod H' slidably: mounted in a boss 72 on the back of. the plate: holder is a,.U-shape.d channel member 13. into which thelowerend of the photographic plate P. is inserted. It will be understood that the lower portion of the photographic plate supported in member 13 is not in the field of the objective lensand need not have emulsion thereon, unlesstwo sets of pictures are to bemade on one plate in. which case the entire plate can be coated with. emulsion and the plate reversed. end-for-end in: the member -13 between exposures. The forward endaof the plate holder. is provided with. a, re;- tractable dark slide. which lies in front of: the Dhotographicplate when itis in its insertedpositionshown iIlFig. 13,.so that after. theyplatej is loaded inthe holderinadark room,'i,t can be: brought out into, the light for. placing theholder. on the camera withoutdangerof fogging thefilm. afterithe loaded holder is properly placed onthe: coverplates 64, the dark slideis removed andthe-v rod H is pushed inwardly. by the use of. knob 15 until the face of the photographic-plate, comes. against three spaced locating stops 16 which accurately position the plate in the focal plane.

The rod- 1 I is then clamped against movement byturning clampingsorew T! which draws anonrotatable bushing 78. into clamping relation with the rod, as shown in Fig. 12.-

In order to accurately initially position the. plate locating stops 16, they are mountedon a.

triangular-shaped rigidplate 19 of theformbest...

shown in Fig..15. This plate!!! is, in turn, providedswith'a post 8!] extending at right angles; therefrom and slideably engaging a relatively longbore8l formed-in. the rear wall ofthecover plate witha good fit for rigidly supporting the; platefis relativeto the focal. plane. Plate 19. is. adapted to be held in any adjusted position by a set screw 82 engaging the post thereof. In; order to initiallyadjust the plate 19 andv the locating stops .16. thereon, the set-screw; 82, is loosened... and the plate l9 is moved parallel tothe optical axis until the ends of the locating stopslli lie-in the-focal plane of the objective. Then the set screw 82 is turneddow-n to lock the plate19 in this position. Theend of post 88 is provided with a tapped hole 83 intowhich a screw canube. threaded to provide a handle for shifting the plate it back and forth until properly adjusted.

Any one .of. several different procedures might...

bex-usedto. accurately adjust plate l9 relative-.to;

the-focal plane of the camera and to insure. a

fdisk... One way is to use a micrometer gauge.

Since the face of the cover plate 64 is a finished face, then by placing a glass plate equal in thickness to the photographic plate against the locating stop 16, the plate '19 can be adjusted until the glass plate is at such a distance from the noted reference surface to leave the desired .003" clearance between the face of the plate and the capping shutter [5. Another way is to place .003 shims between the capping shutter I and the scanning disk l3 and between the shutter and a glass plate having the same thickness as the photographic plate and then adjusting the plate 19 until the locating stops l6 engage the forward face of this test plate.

We will now describe the necessary procedure for taking high-speed motion pictures with the apparatus set forth. First, a photographic plate P is loaded in the plateholder in a dark room. Then the loaded film holder is placed on the cover plate 84 in covering relation with the opening '65 therein. The dark slide 14 is pulled out, the rod H is pushed forwardly until the face of the photographic plate strikes the locating stops l6 and then rod H is locked in position by clamping screw l8. Prior to pulling the dark slide out of the plate holder, the capping shutter l5 should be moved to a cocked position in which it is held by cooperation of bolt 33 and latch member 48, and in which position the slots IS in the shutter are out of alignment with the apertures H1 in the scanning disk l3. Now the motor M is started and the capping shutter I5 and scanning disk is are allowed to come up to speed, i. e., approximately 590 R. P. M. for taking one million pictures per second. When the shutter and scanning disk have settled down to constant speed operation, the 900 exposures are ready to be made. To make the exposures, the solenoid 35 is energized which causes release of latch member 48 whereupon torsion spring 25 takes over to accelerate the shutter-relative to the scanning disk in the direction of rotation of the two. Triggering of the solenoid is usually done by the subject to be photographed. The slight relative rotation of the shutter relative to the scanning disk allows the apertures [4 in the disk to be uncovered during the time it takes the disk to move a distance equal to 900 times the diameter of one or" the apertures in the disk and thus make 900 separate composite exposures on the one photographic plate.

It will be appreciated that the exposed photographic plate after processing cannot be viewed in the ordinary way by the naked eye to observe the pictures thereon. If the plate were so viewed, all that would appear would be an apparently solidly exposed plate with possibly certain of the minute dot areas bein of different density. However, if the exposed processed plate is viewed through an analyzing disk identical with the scanning disk through which it was exposed, or through the scanning disk itself, then the different dots making up each composite picture will be combined and those of other pictures covered so that the pictures will become apparent. This, of course, requires the analyzing grid being registered exac ly with the exposed plate as the scanning disk was when the exposure was made. If the analyzing disk is moved relative to the exposed plate in the same manner as the scanning disk was during exposure, then the several different pictures on the plate will appear in the order in which they were exposed. Accordingly, if a high-speed motion subject is recorded on the plate, by rotating the analyzing disk at a slower rate than the scanning disk was moved during the exposure, then the motion of the subject can be slowed down to any speed for purposes of such analysis.

The best results are obtained when the exposed photographic plate is viewed 'by the use of transmitted light, for then the pictures appear as made up of points of light spaced on a dark back round, and the spreading action of the light passing through the apertures of the analyzing disk help to eliminate the objectionable appearance of dark spaces between the points of light. It" the subject is of the nature that allows it to be viewed satisfactorily as a negative then the exposed photographic plate need only be developed to a negative. However, this negative can be printed and processed to a positive transparency if the nature of the subject requires it or makes it desirable. The present camera can be readily used as an exhibiting device for viewing plates exposed thereon by using the scanning disk l3 as an analyzing disk. To this end, the processed exposed plate could be positioned in a holder much like the plate holder used in exposing so that the exposed plate could be repositioned in the focal plane of the objective lens in exactly the same position it assumed when exposed. To insure proper registration of the exposed plate with the disk l3, means should be provided for moving the plate in three directions relative to the disk. Now if a light source is placed behind the plate which will uniformly illuminate the plate, then the pictures thereon as analyzed by the disk can be projected on a screen by the taking objective of the camera. By rotating the disk [3, the successively exposed composite pictures will be presented in the order of their exposure and the speed of the subject, if a motion picture is on the plate, can be controlled by the speed of rotation of the disk.

Instead of using the capping shutter [5 to prevent double exposures as above set forth, it might be desirable in some instances to use short duration flash lamps to illuminate the subject and to rely upon the duration of the flash being short enough to prevent double exposure. In such a case the subject might be situated in a spot having insufficient illumination to normally affect the film so that no between-the-lens type of shutter would be required to prevent premature fogging of the film. On the other hand, the camera objective l0 could be mounted in a conventional between-the-lens type shutter having a built-in flash synchronizer, not shown, which would fire the lamp and open the shutter in synchronism. Such an arrangement of parts is indicated diagrammatically in Fig. 16 where 84 indicates a conventional between-the-lens type of shutter having a built-in synchronizer, 85 indicates a flash lamp of the gaseous discharge type having a short duration, 86 indicates the source of direct current for supplying power for flashing the lamp and 86' indicates the triggering circuit for firing the lamp, all as is well known in the prior art. The photographic plate and scanning disk are represented by the same reference characters as before, since their individual character and relative disposition will be the same as in the camera disclosed above.

It is also conceivable that it might be desired to record the motion of subjects whose rate of motion is slow enough to allow the apertures in the scanning disk l3 to pass light for as long as /800 of a second before double exposure occurs. Should such be the case, then the capping shutter 217 [5 could be done awaywithancl the duration of exposure controlled by a iconventional betweenthe-lens type. shutter operating at the proper speed and triggered bythe subject-to belphotographed. 1

To allow the capping shutter [5' to be selectively rendered inoperative, and nonexistentyso faras the rest of the apparatus and its function is concerned, the following structure isprov-ided. As best shown in Fig. 10, the driving sleeve 2| has fixed to its periphery a block 81 which lies'adjacent the driving pin 30 extending through drive shaft 25. In threaded engagement with the-end of driving pin 30 is a stop screw 88, the:end-of which is adapted to engage the radialface 88of the block 81 To render the cappingshutter l5 inoperative, or to hold it in apositionwhere'the slots [6 therein are in alignmentwith-the apertures M in the scanning disk l3,'the stop screw 83 is turned down so as to rotate the shutter relative to the disk until it is in its open position. When the capping shutter l5is to be used, the stop screw 88 is backed off andoutof-engagement with the block 81.

This apparatus and method of photography carried out thereby is not limited to taking motion pictures, but could be used for. photographing a plurality of different still subjects on the same photographic plate to be viewed in succession for presenting a changeable picture display. -If the camera is to beused tothis end, each exposure would be made with the disk 13 stationary rela-- tive to the photographic plate, and the disk will be indexed relative to the plate by a: distance equal to the diameter of the'apertures' l4 between each exposure. Under these'conditions the "exposures could be made by the use of a conventional between-the-lens type shutter andithec'apping shutter would be moved. to and held in its inoperative position by the means above described. With the dimensions given above by way of example it would be possible-for oneto photograph as many as 900 different-still composite pictures on a single 4" x 5 photographic-plate, "each pi'cture being substantially 4-x 5-"in"size s as -t0 permit ready viewing without magnification. As before, these composite pictures-when processed Would be viewed and analyzed *through a d-isk exactly like that through 'which the exposures were made, the disk being indexed relative to the processed plate in exactly'thewayit'was-during the exposure and thus'providea 'changeable-picture program consisting of 900 different} pictures.

though we have shown and described certain specific embodiments of our invention, we are fully aware that many modifications-thereof are possible. Our invention therefore-is not tobe limited to the particular details shown'and describedbut is intended toinclude all modifications coming within the scope of the-appended.

claims.

Having thus describedourinvention, what' we claim is new and desire to secure by Betters Patent of the United States is:

1. Aphotographic camera comprising'in combination a camera body having -anwopeniback; an objective on the frontwall of said'-'camera body; means for locating a light-sensitivesurface in the focal plane of said objective through said opening in the camera back so'thatza-given area of said surface will be covered bythedmage projected by said objective; a scanning diskrotatably mounted substantially in the focal .plane 1 of said objective in front of saidlight-sensitivesur- .face, and comprising a circular' disk generally sufficient to cover one dimension of the sensitive surface to be scanned, each aperture of each group :spacedfrom the next adjacent aperture tive so that a given area of said surface will be covere'd by the image projected by said objective;

dot-like, light-transmitting apertures, each having-substantially the-same diameter d,'the apertures disposed in'groups extending spirally of the-face of said disk and each group of apertures being concentric with all others and spaced from the next adjacent group by n times the diameter of the'apertures, the number of groups being in-thatngroup by a distance equal at least to the diameter oftlie apertures in a direction radially of the disk and lays: times the diameter of the apertures ma circumferential direction, whereby the d'isk'canrotate through an arcequal to n d before a given portion of said surface will be scanned by two apertures and a minimum of 12x33 separatedotdike pattern exposures will be made on'said'surface when the'disk is rotated through an are equal to n d, and means for rotating said scanningdisk relative to said light-sensitive surfaceso that-each of said apertures will expose different :and previously unexposedv portions of said surface in succession.

-2. 'A photographic camera comprising in combination an objective; means for locating a lightsensitive surface in the focal plane of said objeca scanningdisk rotatably mounted substantially in-the focal plane of said objective in front of said light-sensitiye surface, and comprising a circular disk generally opaque to the rays to which-said light sensitive surface is sensitive and provided with a multiplicity of substantially equally spaced, individual dot-like, light-transmitting 'apertures," each having substantially the same diameter d,.the apertures disposed in groups extending spirally of the face of said disk and eachegroup of apertures being concentric with all others-and spaced from the next adjacent rgroupjby ntimes the diameter of the apertures,

the number of-groups being sufficient to cover one dimension of the sensitive surface to be scanned, "each aperture of each group spaced fromthe-next "adjacent aperture in thatgroup b'y a distance equal at least to the diameter of the-apertures in a direction radially of the disk andby x timesthe diameter of the apertures in a circumferential direction,whereby the disk can rotate-through an are equal to nXd before a .given portion ofsaid surface will be scanned by two apertures and a minimum of n x separate dot-likepattern exposures will be made on said surface when the disk'is rotated through an are equal to=n d; andim-eans for rotating said scanning disk'across said light-sensitive surface so that eachofsaidapertures will expose different and previously-unexposed portions of said surface in succession.

:3. ,An apparatus for photographing high speed -motion pictures comprising in combination an mounted substantially in thefoc'al plane of said 'obje'ctive in front ofsaid light-sensitive surface,

and provided with a plurality-of dot-likelighttransmitting apertures individually spaced and collectively distributed so that said'given area of thelight-sensitive surface will be covered by a 19 dot pattern of light passing through said apertures in any relative position of said surface and plate and said scanning plate and light-sensitive surface can move relative to one another in a given direction by a distance equal to more than fifty times the diameter of one of said apertures before reexposing a portion of said surface previously exposed by another aperture; means for continuously moving said scanning plate and said light-sensitive surface relative to one another at a relatively high speed; a shutter for cutting light off from said focal plane; and means opening said shutter and maintaining it open for only so long as the individual apertures ar successively uncovering previously unexposed port-ions of said light-sensitive surface.

4. An apparatus for photographing high-speed motion pictures comprising in combination an objective; means for locating a light-sensitive surface in the focal plane of said objective; a

scanning disk rotatably mounted substantially in the focal plane of said objective in front of said light-sensitive surface, and provided with a plurality of dot-like light-transmitting apertures collectively distributed over the disk so that in any position of the disk the surface will be covered by a dot pattern of light of substantially the same overall dimensions as the surface and said apertures individually spaced circumferentially and radially of said disk so that said disk can rotate through a given arc equal to many times the diameter of one of said apertures relative to said sensitive surface before any aperture will scan the same portion of said surface as scanned by any other aperture, means for continuously rotating said disk at a known speed, means for passing light through said scanning disk to said focal plane for a time equal to, or less than, the time required for said disk to rotate through said given are to expose the sensitive surface and prevent double exposure of any portion thereof.

5. A high-speed motion picture camera comprising in combination an objective; means for locating a light-sensitive surface in the focal plane of said objective; a scanning disk rotatably mounted substantially in the focal plane of said objective in front of said light-sensitive surface, and provided with a plurality of similar dot-like light-transmitting apertures collectively distributed over the disk so that in any position of the disk the light-sensitive surface will be covered by a dot pattern of light of substantially the same overall dimensions as the surface and said apertures individually spaced so that said disk can rotate through a given arc relative to said sensitive surface before any aperture will scan the same portion of said surface as scanned by any other aperture; means for continuously rotating said disk at a known high rate of speed; a shutter normally cutting light off from said focal plane; and means for operating said shutter to pass light to said focal plane for a time equal to, or less than, the time required for said disk to rotate through said given are to expose the sensitive surface but prevent double exposure of any portion thereof.

6. A high-speed motion picture camera comprising in combination an objective; means for locating a light-sensitive surface in the focal plane of said objective; a scanning disk rotatably mounted substantially in the focal plane of said objective in front of said light-sensitive surface, and provided with a plurality of dot-like lighttransmitting apertures collectively distributed over the disk so that in any position of the disk the light-sensitive surface will be covered by a dot pattern of light of substantially the same overall dimensions as the surface and said apertures individually spaced so that said disk can rotate through a given arc relative to said sensitive surface before any aperture will scan the same portion of said surface as scanned by any other aperture; means for continuously rotating said disk at a known speed; a capping shutter located substantially in the focal plane adjacent said disk and movable between a normal closed position, wherein it covers the apertures in said disk, and an open position, wherein it uncovers the apertures in said disk to permit light to pass therethrough; and means for selectively moving said capping shutter to its open position at a given time, leaving it open not longer than it takes said disk to rotate through said given are to completely expose the sensitive surface, and then closing it.

'7. A high-speed motion picture camera comprising in combination an objective; means for locating a light-sensitive surface in the focal plane of said objective; a scanning disk rotatably mounted substantially in the focal plane of said objective in front of said light-sensitive surface, and provided with a plurality of dot-like lighttransmitting apertures collectively distributed over the disk so that in any position of the disk the light-sensitive surface will be covered by a dot pattern of light of substantially the same overall dimesions as the surface and said apertures individually spaced so that said disk can rotate through a given arc relative to said sensitive surface before any aperture will scan the same portion of said surface as scanned by any other aperture; means for continuously rotating said disk at a known speed; a capping shutter in the form of a disk rotatably disposed substantially in the focal plane in parallel relation with said scanning disk, and provided with a plurality of light-transmitting apertures corresponding in number and disposition to the apertures in said scanning disk, the apertures in said shutter being elongated in the direction of movement thereof to uncover and, leave uncovered for a predetermined time, the apertures in said scanning disk when the two are rotated relative to one another; means tending to rotate said shutter relative to said scanning disk from a cooked position, wherein the elongated apertures therein are out of alignment with the scanning apertures, through an open position, wherein the apertures in the disk and shutter are aligned, and to a closed position to expose the sensitive surface; means for cocking said shutter; means for rotating said shutter and scanning disk at th same speed while the shutter is in its cocked position; and means for selectively releasing said shutter from its cocked position at a desired instant.

8. A high-speed motion picture camera comprising in combination an objective; means for locating a light-sensitive surface in the focal p ane of said objective; a scanning disk rotatably mounted substantially in the focal plane of said objective in front of said light-sensitive surface, and provided with a plurality of dot-like lighttransmitting apertures collectively distributed over the disk so that in any position of the disk the light-sensitive surface will be covered by a dot pattern of light of substantially the same overall dimensions as the surface and said apertures individually spaced so that said disk can rotate through a given arc relative to said sensitive surface before any aperture will scan the same portion of said surface as scanned by any other aperture; means for continuously rotating said disk at a known speed; a capping shutter in the form of a disk rotatably disposed substantially in the focal plane coaxially with said scanning disk, and provided with a. plurality of lighttransmitting apertures corresponding in number and disposition to the apertures in said scanning disk, the apertures in said shutter being elongated in the direction of movement thereof to uncover, and leave uncovered for a predetermined time, the apertures in said disk when the shutter and disk are rotated relative to one another; a spring tending to rotate said shutter relative to said scanning disk from a cooked position, wherein the apertures in the shutter and disk are out of alignment, through an open position, wherein the apertures in the disk and shutter are in alignment, and to a closed position to expose the sensitive surface; a releasable clutch for holding said shutter in its cocked position and connecting it in driving relation to said disk so that the two are driven at the same speed; and means for selectively releasing said clutch at a desired instant to free said shutter from its cocked position.

9. A high-speed motion picture camera according to claim 8 in which said releasable clutch comprises a driving lug fixed to said shutter; a driving bar mounted on said disk to move to and from a normal operative position in which said driving lug engages a portion thereof when the shutter is cocked to hold said shutter in a cooked position while positively connecting said disk and shutter for combined rotation; and a solenoid for moving said driving bar to its inoperative position when energized and in which position the driving lug is released to allow the shutter to move relative to the disk under the action of its spring driving means to make the exposure.

10. A high-speed motion picture camera comprising in combination an objective; means for locating a light-sensitive surface in the focal plane of said objective; a scanning disk rotatably mounted substantially in the focal plane of said objective in front of said light-sensitive surface, and provided with a plurality of dot-like lighttransmitting apertures collectively distributed over the disk so that in any position of the disk the light-sensitive surface will be covered by a dot pattern of light substantially the same overall dimensions as said surface, and said apertures individually spaced so that said disk can rotate through a given are relative to said surface before any aperture will scan the same portion of said surface as scanned by any other aperture; 2. capping shutter located substantially in the focal plane adjacent said disk and rotatable relative to said disk between normal closed positions, wherein it uncovers the apertures in said disk, and an open position, wherein it uncovers the apertures in said disk to permit light to pass therethrough, means for rotating said disk and shutter together with the shutter in one of its closed positions and selectively rotating said shutter relative to said disk to open the shutter, said last mentioned means including a rotatable shaft on which said shutter is fixed; a sleeve encircling said shaft and carrying said disk; means for driving said sleeve at a known rate including a gear train; a selectively releasable clutch for 22 positively connecting said shutter to said disk; and a spring tending to rotate said shutter relative to said disk when said clutch is released.

11. A high-speed motion picture camera according to claim 10 including means for changing the gear ratio of said train to change the known rate of rotation of said disk and the speed of exposure; and means for varying the initial tension in said spring in accordance with a selected speed of exposur to insure said shutter being open for only the given arc of rotation of said disk which will prevent double exposure of any portion of said sensitive surface.

12. A high-speed motion picture camera according to claim 10 including means for selectively moving said shutter to its open position and holding it in such position while the shutter and disk rotate together whereby th shutter is inoperative.

13. A high-speed camera comprising in combination an objective; means for locating a lightsensitive surface in the focal plane of said objective; a scanning disk rotatably mounted substantially in the focal plane of said objective in front of said light-sensitive surface and comprising a circular disk generally opaque to the rays to which the light-sensitive surface is sensitive, and provided with a multiplicity of substantially equally spaced, individual dot-like, light-transmitting apertures, each having substantially the same diameter d, the apertures disposed in groups extending spirally of the face of said disk, and each group of apertures being concentric with all others and spaced from the next adjacent group by n times the diameter of the apertures, the number of groups being sufficient to cover one dimension of said sensitive surface to be scanned, each aperture of each group spaced from the next adjacent aperture in that group by a distance equal to the diameter of the apertures in a direction radially of the disk and by 1: times the diameter of the apertures in a circumferential direction, whereby the disk can rotate through an arc equal to nXd before a given portion Of said surface will be scanned by two apertures and a minimum of nXx separate dotlike pattern exposures will be made on said surface when the disk is rotated through an are equal to n d, means for continuously rotating said disk at a known speed; a shutter normally cutting light off from said focal plane; and means for operating said shutter to pass light to said focal plane for a time equal to, or less than, the time required for said disk to rotate through said arc equal to nXd to expose the sensitive surface but to prevent double exposure of any portion thereof.

FORDYCE E. 'IUTTLE. WILLIAM BORNEMAN'N.

REFERENCES CITED The following references are of record in the file of this patent:

UNITED STATES PATENTS Number Name Date 1,000,323 Butler Aug. 8, 1911 1,260,682 Kanolt Mar. 26, 1918 1,719,756 Clay July 2, 1929 1,780,191 Huebner Nov. 4, 1930 2,185,610 Stephen et al. Jan. 2, 1940 

